Internet Engineering Task Force (IETF) J. Arkko
Request for Comments: 6180 Ericsson
Category: Informational F. Baker
ISSN: 2070-1721 Cisco Systems
May 2011
Guidelines for Using IPv6 Transition Mechanisms during IPv6 Deployment
Abstract
The Internet continues to grow beyond the capabilities of IPv4. An
expansion in the address space is clearly required. With its
increase in the number of available prefixes and addresses in a
subnet, and improvements in address management, IPv6 is the only real
option on the table. Yet, IPv6 deployment requires some effort,
resources, and expertise. The availability of many different
deployment models is one reason why expertise is required. This
document discusses the IPv6 deployment models and migration tools,
and it recommends ones that have been found to work well in
operational networks in many common situations.
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for informational purposes.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Not all documents
approved by the IESG are a candidate for any level of Internet
Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc6180.
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RFC 6180 IPv6 Transition Guidelines May 20111. Introduction
The Internet continues to grow beyond the capabilities of IPv4. The
tremendous success of the Internet has strained the IPv4 address
space, which is no longer sufficient to fuel future growth. At the
time of this writing, August 2010, the IANA "free pool" contains only
14 unallocated unicast IPv4 /8 prefixes. Credible estimates based on
past behavior suggest that the Regional Internet Registries (RIRs)
will exhaust their remaining address space by early 2012, apart from
the development of a market in IPv4 address space. An expansion in
the address space is clearly required. With its increase in the
number of available prefixes and addresses in a subnet, and
improvements in address management, IPv6 is the only real option on
the table.
John Curran, in "An Internet Transition Plan" [RFC5211], gives
estimated dates for significant points in the transition; while the
tail of the process will likely be long, it is clear that deployment
is a present reality and requirement.
Accordingly, many organizations have employed or are planning to
employ IPv6 in their networks. Yet, IPv6 deployment requires some
effort, resources, and expertise. This is largely a natural part of
maintaining and evolving a network: changing requirements are taken
into account in normal planning, procurement, and update cycles.
Very large networks have successfully adopted IPv6 alongside IPv4,
with surprisingly little effort.
However, in order to successfully make this transition, some amount
of new expertise is required. Different types of experience will be
required: basic understanding of IPv6 mechanisms, debugging tools,
product capabilities and caveats when used with IPv6, and so on. The
availability of many different IPv6 deployment models and tools is an
additional reason why expertise is required. These models and tools
have been developed over the years at the IETF, some for specific
circumstances and others for more general use. They differ greatly
in their principles of operation. Over time, views about the best
ways to employ the tools have evolved. Given the number of options,
network managers are understandably confused. They need guidance on
recommended approaches to IPv6 deployment.
The rest of this document is organized as follows. Section 2
introduces some terminology, Section 3 discusses some of the general
principles behind choosing particular deployment models and tools,
Section 4 goes through the recommended deployment models for common
situations, and Section 5 provides some concluding remarks about the
choice between these models.
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Many networks can follow one of the four scenarios described in this
document. However, variations will certainly occur in the details,
and there will be questions, such as the particular choice of
tunneling solution, for which there is no "one size fits all" answer.
Network managers must each take the responsibility of choosing the
best solution for their own case. This document does not attempt to
provide guidance for all possible networking situations. Also, a
systematic operational plan for the transition is required, but the
details depend entirely on the individual network.
2. Terminology
In this document, the following terms are used.
IPv4/IPv4 NAT: refers to any IPv4-to-IPv4 network address
translation algorithm, both "Basic NAT" and "Network Address/Port
Translator (NAPT)", as defined by [RFC2663].
Dual Stack: refers to a technique for providing complete support for
both Internet protocols -- IPv4 and IPv6 -- in hosts and routers
[RFC4213].
Dual Stack Lite: also called "DS-Lite", refers to a technique that
employs tunneling and IPv4/IPv4 NAT to provide IPv4 connectivity
over IPv6 networks [DS-lite].
IPv4-only domain: as defined in [RFC6144], a routing domain in which
applications can only use IPv4 to communicate, whether due to host
limitations, application limitations, or network limitations.
IPv6-only domain: as defined in [RFC6144], a routing domain in which
applications can only use IPv6 to communicate, whether due to host
limitations, application limitations, or network limitations.
NAT-PT: refers to a specific, old design of a Network Address
Translator - Protocol Translator defined in [RFC2766] and
deprecated due to the reasons stated in [RFC4966].
3. Principles
The primary goal is to facilitate the continued growth of the
networking industry and deployment of Internet technology at
relatively low capital and operational expense without destabilizing
deployed services or degrading customer experience. This is at risk
with IPv4 due to the address runout; economics teaches us that a
finite resource, when stressed, becomes expensive, either in the
actual cost of the resource or in the complexity of the technology
and processes required to manage it. It is also at risk while both
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IPv4 and IPv6 are deployed in parallel, as it costs more to run two
technologies than one. To this end, since IPv4 clearly will not
scale to meet our insatiable requirements, the primary technical
goals are the global deployment of IPv6 both in the network, in its
service infrastructure, and by applications, resulting in the end of
the requirement to deploy two IP versions and the obsolescence of
transitional mechanisms. Temporary goals in support of this focus on
enabling parts of the Internet to employ IPv6 and disable IPv4 before
the entire Internet has done so.
3.1. Goals
The end goal is network-wide native IPv6 deployment, resulting in the
obsolescence of transitional mechanisms based on encapsulation,
tunnels, or translation, and also resulting in the obsolescence of
IPv4. Transition mechanisms, taken as a class, are a means to an
end, to simplify the process for the network administration.
However, the goals, constraints, and opportunities for IPv6
deployment differ from one case to another. There is no single right
model for IPv6 deployment, just like there is no one and only model
for IPv4 network design. Some guidelines can be given, however.
Common deployment models that have been found to work well are
discussed in Section 4, and the small set of standardized IETF
migration tools support these models. But first it may be useful to
discuss some general principles that guide our thinking about what is
a good deployment model.
It is important to start the deployment process in a timely manner.
Most of the effort is practical -- network audit, network component
choices, network management, planning, implementation -- and at the
time of this writing, reasonably easily achievable. There is no
particular advantage to avoiding dealing with IPv6 as part of the
normal network planning cycle. The migration tools already exist,
and while additional features continue to be developed, it is not
expected that they radically change what networks have to do. In
other words, there is no point in waiting for an improved design.
There are only a few exceptional networks where coexistence with IPv4
is not a consideration at all. These networks are typically new
deployments, strictly controlled by a central authority, and have no
need to deal with legacy devices. For example, specialized machine-
to-machine networks that communicate only to designated servers, such
as Smart Grids, can easily be deployed as IPv6-only networks. Mobile
telephone network operators, especially those using 3GPP (Third
Generation Partnership Project), have seriously considered IPv6-only
operation, and some have deployed it. Research networks that can be
separated from the IPv4 Internet to find out what happens are also a
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candidate. In most other networks, IPv4 has to be considered. A
typical requirement is that older, IPv4-only applications, systems,
or services must be accommodated. Most networks that cross
administrative boundaries or allow end-user equipment have such
requirements. Even in situations where the network consists of only
new, IPv6-capable devices, it is typically required that the devices
be able to communicate with the IPv4 Internet.
It is expected that after a period of supporting both IPv4 and IPv6,
IPv4 can eventually be turned off. This should happen gradually.
For instance, a service provider network might stop providing IPv4
service within its own network, while still allowing its IPv6
customers to access the rest of the IPv4 Internet through overlay,
proxy, or translation services. Regardless of progress in supporting
IPv6, it is widely expected that some legacy applications and some
networks will continue to run only over IPv4 for many years. All
deployment scenarios need to deal with this situation.
3.2. Choosing a Deployment Model
The first requirement is that the model or tool actually allow
communications to flow and services to appropriately be delivered to
customers without perceived degradation. While this sounds too
obvious to even state, it is sometimes not easy to ensure that a
proposed model does not have failure modes related to supporting
older devices, for instance. A network that is not serving all of
its users is not fulfilling its task.
The ability to communicate is far more important than fine-grained
performance differences. In general, it is not productive to focus
on the optimization of a design that is intended to be temporary,
such as a migration solution necessarily is. Consequently, existing
tools are often preferred over new ones, even if for some specific
circumstance it would be possible to construct a slightly more
efficient design.
Similarly, migration tools that can be disposed after a period of co-
existence are preferred over tools that require more permanent
changes. Such permanent changes may incur costs even after the
transition to IPv6 has been completed.
Looking back on the deployment of Internet technology, some of the
factors, as described in [RFC5218] and [Baker.Shanghai], that have
been important for success include:
o The ability to offer a valuable service. In the case of the
Internet, connectivity has been this service.
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o The ability to deploy the solution in an incremental fashion.
o Simplicity. This has been a key factor in making it possible for
all types of devices to support the Internet protocols.
o Openly available implementations. These make it easier for
researchers, start-ups, and others to build on or improve existing
components.
o The ability to scale. The IPv4 Internet grew far larger than its
original designers had anticipated, and scaling limits only became
apparent 20-30 years later.
o The design supports robust interoperability rather than mere
correctness. This is important in order to ensure that the
solution works in different circumstances and in an imperfectly
controlled world.
Similar factors are also important when choosing IPv6 migration
tools. Success factors should be evaluated in the context of a
migration solution. For instance, incremental deployability and lack
of dependencies to components that are under someone else's control
are key factors.
It is also essential that any chosen designs allow the network to be
maintained, serviced, diagnosed, and measured. The ability of the
network to operate under many different circumstances and surprising
conditions is a key. Any large network that employs brittle
components will incur significant support costs.
Properly executed IPv6 deployment normally involves a step-wise
approach where individual functions or parts of the network are
updated at different times. For instance, IPv6 connectivity has to
be established and tested before DNS entries with IPv6 addresses can
be provisioned. Or, specific services can be moved to support IPv6
earlier than others. In general, most deployment models employ a
very similar network architecture for both IPv4 and IPv6. The
principle of changing only the minimum amount necessary is applied
here. As a result, some features of IPv6, such as the ability to
have an effectively unlimited number of hosts on a subnet, may not be
available in the short term.
4. Guidelines for IPv6 Deployment
This section presents a number of common scenarios along with
recommended deployment tools for them. We start from the most
obvious deployment situation where native connectivity is available
and both IP versions are used. Since native IPv6 connectivity is not
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available in all networks, our second scenario looks at ways of
arranging such connectivity over the IPv4 Internet. The third
scenario is more advanced and looks at a service provider network
that runs only on IPv6 but that is still capable of providing both
IPv6 and IPv4 services. The fourth and most advanced scenario
focuses on translation, at the application or the network layer.
Note that there are many other possible deployment models and
existing specifications to support such models. These other models
are not necessarily frowned upon. However, they are not expected to
be the mainstream deployment models, and consequently, the associated
specifications are typically not IETF Standards Track RFCs. Network
managers should not adopt these non-mainstream models lightly,
however, as there is little guarantee that they work well. There are
also models that are believed to be problematic. An older model of
IPv6-IPv4 translation (NAT-PT) [RFC2766] suffers from a number of
drawbacks arising from, for example, its attempt to capture DNS
queries on path [RFC4966]. Another example regarding the preference
to employ tunneling instead of double translation will be discussed
later in this document.
4.1. Native Dual Stack
The simplest deployment model is dual stack: one turns on IPv6
throughout one's existing IPv4 network and allows applications using
the two protocols to operate as ships in the night. This model is
applicable to most networks -- home, enterprise, service provider, or
content provider network.
The purpose of this model is to support any type of device and
communication, and to make it an end-to-end choice which IP version
is used between the peers. There are minimal assumptions about the
capabilities and configuration of hosts in these networks. Native
connectivity avoids problems associated with the configuration of
tunnels and Maximum Transmission Unit (MTU) settings. As a result,
these networks are robust and reliable. Accordingly, this is the
recommended deployment model for most networks and is supported by
IETF standards such as dual stack [RFC4213] and address selection
[RFC3484]. Similarly, while there are some remaining challenges,
this model is also preferred by many service providers and network
managers [RFC6036] [IPv6-only-experience].
The challenges associated with this model are twofold. First, while
dual stack allows each individual network to deploy IPv6 on their
own, actual use still requires participation from all parties between
the peers. For instance, the peer must be reachable over IPv6, have
an IPv6 address to itself, and advertise such an address in the
relevant naming service (such as the DNS). This can create a
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situation where IPv6 has been turned on in a network, but there is
little actual traffic. One direct way to affect this situation is to
ensure that major destinations of traffic are prepared to receive
IPv6 traffic. Current Internet traffic is highly concentrated on
selected content provider networks, and making a change in even a
small number of these networks can have significant effects. This
was recently observed when YouTube started supporting IPv6
[networkworld.youtube]. There are scenarios where these means are
insufficient. The following sections discuss deployment models that
enable parts of the network to deploy IPv6 faster than other parts.
The second challenge is that not all applications deal gracefully
with situations where one of the alternative destination addresses
works unreliably. For instance, if IPv6 connectivity is unreliable,
it may take a long time for some applications to switch over to IPv4.
As a result, many content providers are shying away from advertising
IPv6 addresses in DNS. This in turn exacerbates the first challenge.
Long term, the use of modern application toolkits and APIs solves
this problem. In the short term, some content providers and user
network managers have made a mutual agreement to resolve names to
IPv6 addresses. Such agreements are similar to peering agreements
and have been seen as necessary by many content providers. These
"whitelisting" practices have some downsides as well, however. In
particular, they create a dependency on an external party for moving
traffic to IPv6. Nevertheless, there are many types of traffic in
the Internet, and only some of it requires such careful coordination.
Popular peer-to-peer systems can automatically and reliably employ
IPv6 connectivity where it is available, for instance.
Despite these challenges, the native dual-stack connectivity model
remains the recommended approach. It is responsible for a large part
of the progress on worldwide IPv6 deployment to date. The largest
IPv6 networks -- notably, national research and education networks,
Internet II, RENATER, and others -- employ this approach.
The original intent of dual stack was to deploy both IP versions
alongside each other before IPv4 addresses were to run out. As we
know, this never happened and deployment now has to take place with
limited IPv4 addresses. Employing dual stack together with a
traditional IPv4 address translator (IPv4/IPv4 NAT) is a very common
configuration. If the address translator is acceptable for the
network from a pure IPv4 perspective, this model can be recommended
from a dual-stack perspective as well. The advantage of IPv6 in this
model is that it allows direct addressing of specific nodes in the
network, creating a contrast to the translated IPv4 service, as noted
in [RFC2993] and [shared-addressing-issues]. As a result, it allows
the construction of IPv6-based applications that offer more
functionality.
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There may also be situations where a traditional IPv4 address
translator is no longer sufficient. For instance, in typical
residential networks, each subscriber is given one global IPv4
address, and the subscriber's IPv4/IPv4 NAT device may use this
address with as many devices as it can handle. As IPv4 address space
becomes more constrained and without substantial movement to IPv6, it
is expected that service providers will be pressured to assign a
single global IPv4 address to multiple subscribers. Indeed, in some
deployments this is already the case. The dual-stack model is still
applicable even in these networks, but the IPv4/IPv4 Network Address
Transition (NAT) functionality may need to be relocated and enhanced.
On some networks it is possible to employ overlapping private address
space [L2-NAT] [DS-extra-lite]. Other networks may require a
combination of IPv4/IPv4 NAT enhancements and tunneling. These
scenarios are discussed further in Section 4.3.
4.2. Crossing IPv4 Islands
Native IPv6 connectivity is not always available, but fortunately it
can be established using tunnels. Tunneling introduces some
additional complexity. It also increases the probability that the
Path MTU algorithm will be used, as many implementations derive their
default MTU from the Ethernet frame size; ICMP filtering interacts
poorly with the Path MTU algorithm in [RFC1981]. However, its
benefit is that it decouples addressing inside and outside the
tunnel, making it easy to deploy IPv6 without having to modify
routers along the path. Tunneling should be used when native
connectivity cannot be established, such as when crossing another
administrative domain or a router that cannot be easily reconfigured.
There are several types of tunneling mechanisms, including manually
configured IPv6-over-IPv4 tunnels [RFC4213], 6to4 [RFC3056],
automatic host-based tunnels [RFC4380], tunnel brokers [RFC3053],
running IPv6 over MPLS with IPv6 Provider Edge Routers (6PE)
[RFC4798], the use of Virtual Private Networks (VPNs) or mobility
tunnels to carry both IPv4 and IPv6 [RFC4301] [RFC5454] [RFC5555]
[RFC5844], and many others. More advanced solutions provide a mesh-
based framework of tunnels [RFC5565].
On a managed network, there are no major challenges with tunneling
beyond the possible configuration and MTU problems. Tunneling is
very widely deployed both for IPv6 connectivity and other reasons,
and is well understood. In general, the IETF recommends that
tunneling be used if it is necessary to cross a segment of IP version
X when communicating from IP version Y to Y. An alternative design
would be to employ protocol translation twice. However, this design
involves problems similar to those created by IPv4 address
translation and is largely untried technology in any larger scale.
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On an unmanaged network, however, there have been a number of
problems. In general, solutions aimed at early adopters (such as
6to4) have at times caused IPv6 connectivity to appear to be
available on a network when in fact there is no connectivity. In
turn, this has lead to the content providers needing to serve IPv6
results for DNS queries only for trusted peers with known high-
quality connectivity.
The IPv6 Rapid Deployment (6RD) [RFC5969] approach is a newer version
of the 6to4 tunneling solution without the above drawbacks. It
offers systematic IPv6 tunneling over IPv4 across an ISP,
correspondence between IPv4 and IPv6 routing, and can be deployed
within an ISP without the need to rely on other parties.
4.3. IPv6-Only Core Network
An emerging deployment model uses IPv6 as the dominant protocol at a
service provider network, and tunnels IPv4 through this network in a
manner converse to the one described in the previous section. There
are several motivations for choosing this deployment model:
o There may not be enough public or private IPv4 addresses to
support network management functions in an end-to-end fashion,
without segmenting the network into small parts with overlapping
address space.
o IPv4 address sharing among subscribers may involve new address
translation nodes within the service provider's network. IPv6 can
be used to reach these nodes. Normal IPv4 routing is insufficient
for this purpose, as the same addresses would be used in several
parts of the network.
o It may be simpler for the service provider to employ a single-
version network.
The recommended tool for this model is Dual Stack Lite [DS-lite].
Dual Stack Lite both provides relief for IPv4 address shortage and
makes forward progress on IPv6 deployment, by moving service provider
networks and IPv4 traffic over IPv6. Given the IPv6 connectivity
that Dual Stack Lite runs over, it becomes easy to provide IPv6
connectivity all the way to the end users as well.
4.4. IPv6-Only Deployment
Our final deployment model breaks the requirement that all parties
must upgrade to IPv6 before any end-to-end communications use IPv6.
This model makes sense when the following conditions are met:
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o There is a fact or requirement that there be an IPv4-only domain
and an IPv6-only domain.
o There is a requirement that hosts in the IPv4-only domain access
servers or peers in the IPv6-only domain and vice versa.
This deployment model would fit well, for instance, a corporate or
mobile network that offers IPv6-only networking but where users still
wish to access content from the IPv4 Internet.
When we say "IPv4-only" or "IPv6-only", we mean that the applications
can communicate only using IPv4 or IPv6; this might be due to lack of
capabilities in the applications, host stacks, or the network; the
effect is the same. The reason to switch to an IPv6-only network may
be a desire to test such a configuration or to simplify the network.
It is expected that as IPv6 deployment progresses, the second reason
will become more prevalent. One particular reason for considering an
IPv6-only domain is the effect of overlapping private address space
to applications. This is important in networks that have exhausted
both public and private IPv4 address space and where arranging an
IPv6-only network is easier than dealing with the overlapping address
space in applications.
Note that the existence of an IPv6-only domain requires that all
devices are indeed IPv6 capable. In today's mixed networking
environments with legacy devices, this cannot always be guaranteed.
But, it can be arranged in networks where all devices are controlled
by a central authority. For instance, newly built corporate networks
can ensure that the latest device versions are in use. Some networks
can also be engineered to support different services over an
underlying network and, as such, can support IPv6-only networking
more easily. For instance, a cellular network may support IPv4-only
connectivity for the installed base of existing devices and IPv6-only
connectivity for incremental growth with newer IPv6-capable handsets.
Similarly, a broadband ISP may support dual-stack connectivity for
customers that require both IPv4 and IPv6, and offer IPv6-only and
NAT64 service for others. In the case of 3GPP and DOCSIS 3.0 access
networks, the underlying access network architecture allows the
flexibility to run different services in parallel to suit the various
needs of the customer and the network operator.
It is also necessary for the network operator to have some level of
understanding of what applications are used in the network, enabling
him to ensure that any communication exchange is in fact predictable,
capable of using IPv6, and translatable. In such a case, full
interoperability can be expected. This has been demonstrated with
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some mobile devices, for instance. Note that the requirements on
applications are similar to those in networks employing IPv4 NAT
technology.
One obvious IPv6-only deployment approach applies to applications
that include proxies or relays. One might position a web proxy, a
mail server, or a SIP (Session Initiation Protocol) and media stream
back-to-back user agent across the boundary between IPv4 and IPv6
domains, so that the application terminates IPv4 sessions on one side
and IPv6 sessions on the other. Doing this preserves the end-to-end
nature of communications from the gateway to the communicating peer.
For obvious reasons, this solution is preferable to the
implementation of Application Layer Gateways in network-layer
translators.
The other approach is network-layer IPv4/IPv6 translation as
described in "IPv4/IPv6 Translation" [RFC6144] [RFC6145] [RFC6146]
[RFC6052] [RFC6147] [FTP64]. IPv4/IPv6 translation at the network
layer is similar to IPv4/IPv4 translation in its advantages and
disadvantages. It allows a network to provide two types of services
to IPv6-only hosts:
o a relatively small set of systems may be configured with IPv4-
mapped addresses, enabling stateless interoperation between IPv4-
only and IPv6-only domains, each of which can use the other as
peers or servers, and
o a larger set of systems with global IPv6 addresses, which can
access IPv4 servers using stateful translation but which are
inaccessible as peers or servers from the IPv4-only domain.
The former service is used today in some university networks, and the
latter in some corporate and mobile networks. The stateless service
is naturally better suited for servers, and the stateful service for
large numbers of client devices. The latter case occurs typically in
a public network access setting. The two services can of course also
be used together. In this scenario, network-layer translation
provides for straightforward services for most applications crossing
the IPv4-only/IPv6-only boundary.
One challenge in this model is that as long as IPv4 addresses are
still shared, issues similar to those caused by IPv4 NATs will still
appear [shared-addressing-issues]. Another challenge relates to
communications involving IPv4 referrals. IPv4-literals within
certain protocols and formats, such as HTML, will fail when passed to
IPv6-only hosts since the host does not have an IPv4 address to
source the IPv4 communications or an IPv4 route. Measurements on the
public Internet show that literals appear in a tiny but measurable
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part of web pages [IPv6-only-experience], though whether this poses a
practical problem is debatable. If this poses a particular problem
for the types of applications in use, proxy configurations could be
modified to use a proxy for the traffic in question, hosts could be
modified to understand how they can map IPv4-literals to IPv6
addresses, or native dual stack could be employed instead.
5. Conclusions
The fundamental recommendation is to turn on IPv6. Section 4
described four deployment models to do that, presented in rough order
of occurrence in the world at the time of this writing. The first
two models are the most widely deployed today. All four models are
recommended by the IETF, though, again, the first two models should
take priority where they are applicable.
As noted in Section 1, variations occur in details, and network
managers are ultimately in charge of choosing the best solution for
their own case. Benefits and challenges discussed in the previous
sections should be considered when weighing deployment alternatives.
The transition mechanisms that operators have deployed have been a
mixed blessing; native dual-stack deployments are not used to their
full extent if peers have not upgraded, tunnel mechanisms that don't
follow the routing of the underlying network have been problematic,
and translation has its faults as well. Nevertheless, operators have
successfully deployed very large networks with these models.
Some additional considerations are discussed below.
o There is a tradeoff between ability to connect as many different
types of devices as possible and the ability to move forward with
deployment as independently as possible. As an example, native
dual stack ensures the best connectivity but requires updates in
peer systems before actual traffic flows over IPv6. Conversely,
IPv6-only networks are very sensitive to what kind of devices they
can support, but can be deployed without any expectation of
updates on peer systems.
o "Greenfield" networks and networks with existing IPv4 devices and
users need to be treated differently. In the latter case, turning
on IPv6 in addition to IPv4 seems the rational choice. In the
former case, an IPv6-only model may make sense.
o The right deployment model choices also vary as time goes by. For
instance, a tunneling solution that makes sense today may become a
native dual-stack solution as the network and devices in the
network evolve. Or, an IPv6-only network becomes feasible when a
sufficient fraction of client devices become IPv6-enabled.
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No matter which deployment model is chosen, many of the important
implications of IPv6 deployment are elsewhere within the network:
IPv6 needs to be taken into account in network management systems and
operations, address assignments, service agreements, firewalls,
intrusion detection systems, and so on.
6. Further Reading
Various aspects of IPv6 deployment have been covered in several
documents. Of particular interest may be the basic dual-stack
definition [RFC4213], application aspects [RFC4038], deployment in
Internet service provider networks [RFC4029] [RFC6036], deployment in
enterprise networks [RFC4057] [RFC4852], IPv6-only deployment
[IPv6-only-experience], and considerations in specific access
networks such as cellular networks [RFC3314] [RFC3574] [RFC4215]
[v6-in-mobile] or 802.16 networks [RFC5181].
This document provides general guidance on IPv6 deployment models
that have been found suitable for most organizations. The purpose of
this document is not to enumerate all special circumstances that may
warrant other types of deployment models or the details of the
necessary transition tools. Many of the special cases and details
have been discussed in the above documents.
7. Security Considerations
While there are detailed differences between the security properties
and vulnerabilities between IPv4 and IPv6, in general they provide a
very similar level of security and are subject to the same threats.
With both protocols, specific security issues are more likely to be
found at the practical level than in the specifications. The
practical issues include, for instance, bugs or available security
mechanisms on a given product. When deploying IPv6, it is important
to ensure that the necessary security capabilities exist on the
network components even when dealing with IPv6 traffic. For
instance, firewall capabilities have often been a challenge in IPv6
deployments.
This document has no impact on the security properties of specific
IPv6 transition tools. The security considerations relating to the
transition tools are described in the relevant documents, for
instance, [RFC4213], [RFC6147], [DS-lite], and [RFC6169].
Arkko & Baker Informational [Page 15]

RFC 6180 IPv6 Transition Guidelines May 2011Appendix A. Acknowledgments
The authors would like to thank the many people who have engaged in
discussions around this topic over the years. Some of the material
in this document comes originally from Fred Baker's presentation in a
workshop in Shanghai [Baker.Shanghai]. In addition, the authors
would like to thank Mark Townsley with whom Jari Arkko wrote an
earlier document [RFC6127]. Brian Carpenter submitted an in-depth
review and provided significant new text. Cameron Byrne provided
significant feedback on the key recommendations in this memo. The
authors would also like thank Dave Thaler, Alain Durand, Randy Bush,
and Dan Wing, who have always provided valuable guidance in this
field. Finally, the authors would like to thank Suresh Krishnan,
Fredrik Garneij, Mohamed Boucadair, Remi Despres, Kurtis Lindqvist,
Shawn Emery, Dan Romascanu, Tim Polk, Ralph Droms, Sean Turner, Tina
Tsou, Nevil Brownlee, and Joel Jaeggli, who have commented on early
versions of this memo.
Authors' Addresses
Jari Arkko
Ericsson
Jorvas 02420
Finland
EMail: jari.arkko@piuha.net
Fred Baker
Cisco Systems
Santa Barbara, California 93117
USA
EMail: fred@cisco.com
Arkko & Baker Informational [Page 20]